예제 #1
0
    def train(self) -> None:
        r"""Main method for DD-PPO.

        Returns:
            None
        """
        self.local_rank, tcp_store = init_distrib_slurm(
            self.config.RL.DDPPO.distrib_backend)
        add_signal_handlers()

        # Stores the number of workers that have finished their rollout
        num_rollouts_done_store = distrib.PrefixStore("rollout_tracker",
                                                      tcp_store)
        num_rollouts_done_store.set("num_done", "0")

        self.world_rank = distrib.get_rank()
        self.world_size = distrib.get_world_size()

        self.config.defrost()
        self.config.TORCH_GPU_ID = self.local_rank
        self.config.SIMULATOR_GPU_ID = self.local_rank
        # Multiply by the number of simulators to make sure they also get unique seeds
        self.config.TASK_CONFIG.SEED += (self.world_rank *
                                         self.config.NUM_PROCESSES)
        self.config.freeze()

        random.seed(self.config.TASK_CONFIG.SEED)
        np.random.seed(self.config.TASK_CONFIG.SEED)
        torch.manual_seed(self.config.TASK_CONFIG.SEED)

        if torch.cuda.is_available():
            self.device = torch.device("cuda", self.local_rank)
            torch.cuda.set_device(self.device)
        else:
            self.device = torch.device("cpu")

        self.envs = construct_envs(
            self.config,
            get_env_class(self.config.ENV_NAME),
            workers_ignore_signals=True,
        )

        ppo_cfg = self.config.RL.PPO
        if (not os.path.isdir(self.config.CHECKPOINT_FOLDER)
                and self.world_rank == 0):
            os.makedirs(self.config.CHECKPOINT_FOLDER)

        self._setup_actor_critic_agent(ppo_cfg)
        self.agent.init_distributed(find_unused_params=True)

        if self.world_rank == 0:
            logger.info("agent number of trainable parameters: {}".format(
                sum(param.numel() for param in self.agent.parameters()
                    if param.requires_grad)))

        observations = self.envs.reset()
        batch = batch_obs(observations, device=self.device)
        batch = apply_obs_transforms_batch(batch, self.obs_transforms)

        obs_space = self.obs_space
        if self._static_encoder:
            self._encoder = self.actor_critic.net.visual_encoder
            obs_space = spaces.Dict({
                "visual_features":
                spaces.Box(
                    low=np.finfo(np.float32).min,
                    high=np.finfo(np.float32).max,
                    shape=self._encoder.output_shape,
                    dtype=np.float32,
                ),
                **obs_space.spaces,
            })
            with torch.no_grad():
                batch["visual_features"] = self._encoder(batch)

        rollouts = RolloutStorage(
            ppo_cfg.num_steps,
            self.envs.num_envs,
            obs_space,
            self.envs.action_spaces[0],
            ppo_cfg.hidden_size,
            num_recurrent_layers=self.actor_critic.net.num_recurrent_layers,
        )
        rollouts.to(self.device)

        for sensor in rollouts.observations:
            rollouts.observations[sensor][0].copy_(batch[sensor])

        # batch and observations may contain shared PyTorch CUDA
        # tensors.  We must explicitly clear them here otherwise
        # they will be kept in memory for the entire duration of training!
        batch = None
        observations = None

        current_episode_reward = torch.zeros(self.envs.num_envs,
                                             1,
                                             device=self.device)
        running_episode_stats = dict(
            count=torch.zeros(self.envs.num_envs, 1, device=self.device),
            reward=torch.zeros(self.envs.num_envs, 1, device=self.device),
        )
        window_episode_stats: DefaultDict[str, deque] = defaultdict(
            lambda: deque(maxlen=ppo_cfg.reward_window_size))

        t_start = time.time()
        env_time = 0
        pth_time = 0
        count_steps: float = 0
        count_checkpoints = 0
        start_update = 0
        prev_time = 0

        lr_scheduler = LambdaLR(
            optimizer=self.agent.optimizer,
            lr_lambda=lambda x: linear_decay(x, self.config.NUM_UPDATES
                                             ),  # type: ignore
        )

        interrupted_state = load_interrupted_state()
        if interrupted_state is not None:
            self.agent.load_state_dict(interrupted_state["state_dict"])
            self.agent.optimizer.load_state_dict(
                interrupted_state["optim_state"])
            lr_scheduler.load_state_dict(interrupted_state["lr_sched_state"])

            requeue_stats = interrupted_state["requeue_stats"]
            env_time = requeue_stats["env_time"]
            pth_time = requeue_stats["pth_time"]
            count_steps = requeue_stats["count_steps"]
            count_checkpoints = requeue_stats["count_checkpoints"]
            start_update = requeue_stats["start_update"]
            prev_time = requeue_stats["prev_time"]

        with (TensorboardWriter(self.config.TENSORBOARD_DIR,
                                flush_secs=self.flush_secs)
              if self.world_rank == 0 else contextlib.suppress()) as writer:
            for update in range(start_update, self.config.NUM_UPDATES):
                if ppo_cfg.use_linear_lr_decay:
                    lr_scheduler.step()  # type: ignore

                if ppo_cfg.use_linear_clip_decay:
                    self.agent.clip_param = ppo_cfg.clip_param * linear_decay(
                        update, self.config.NUM_UPDATES)

                if EXIT.is_set():
                    self.envs.close()

                    if REQUEUE.is_set() and self.world_rank == 0:
                        requeue_stats = dict(
                            env_time=env_time,
                            pth_time=pth_time,
                            count_steps=count_steps,
                            count_checkpoints=count_checkpoints,
                            start_update=update,
                            prev_time=(time.time() - t_start) + prev_time,
                        )
                        save_interrupted_state(
                            dict(
                                state_dict=self.agent.state_dict(),
                                optim_state=self.agent.optimizer.state_dict(),
                                lr_sched_state=lr_scheduler.state_dict(),
                                config=self.config,
                                requeue_stats=requeue_stats,
                            ))

                    requeue_job()
                    return

                count_steps_delta = 0
                self.agent.eval()
                for step in range(ppo_cfg.num_steps):

                    (
                        delta_pth_time,
                        delta_env_time,
                        delta_steps,
                    ) = self._collect_rollout_step(rollouts,
                                                   current_episode_reward,
                                                   running_episode_stats)
                    pth_time += delta_pth_time
                    env_time += delta_env_time
                    count_steps_delta += delta_steps

                    # This is where the preemption of workers happens.  If a
                    # worker detects it will be a straggler, it preempts itself!
                    if (step >=
                            ppo_cfg.num_steps * self.SHORT_ROLLOUT_THRESHOLD
                        ) and int(num_rollouts_done_store.get("num_done")) > (
                            self.config.RL.DDPPO.sync_frac * self.world_size):
                        break

                num_rollouts_done_store.add("num_done", 1)

                self.agent.train()
                if self._static_encoder:
                    self._encoder.eval()

                (
                    delta_pth_time,
                    value_loss,
                    action_loss,
                    dist_entropy,
                ) = self._update_agent(ppo_cfg, rollouts)
                pth_time += delta_pth_time

                stats_ordering = sorted(running_episode_stats.keys())
                stats = torch.stack(
                    [running_episode_stats[k] for k in stats_ordering], 0)
                distrib.all_reduce(stats)

                for i, k in enumerate(stats_ordering):
                    window_episode_stats[k].append(stats[i].clone())

                stats = torch.tensor(
                    [value_loss, action_loss, count_steps_delta],
                    device=self.device,
                )
                distrib.all_reduce(stats)
                count_steps += stats[2].item()

                if self.world_rank == 0:
                    num_rollouts_done_store.set("num_done", "0")

                    losses = [
                        stats[0].item() / self.world_size,
                        stats[1].item() / self.world_size,
                    ]
                    deltas = {
                        k: ((v[-1] - v[0]).sum().item()
                            if len(v) > 1 else v[0].sum().item())
                        for k, v in window_episode_stats.items()
                    }
                    deltas["count"] = max(deltas["count"], 1.0)

                    writer.add_scalar(
                        "reward",
                        deltas["reward"] / deltas["count"],
                        count_steps,
                    )

                    # Check to see if there are any metrics
                    # that haven't been logged yet
                    metrics = {
                        k: v / deltas["count"]
                        for k, v in deltas.items()
                        if k not in {"reward", "count"}
                    }
                    if len(metrics) > 0:
                        writer.add_scalars("metrics", metrics, count_steps)

                    writer.add_scalars(
                        "losses",
                        {k: l
                         for l, k in zip(losses, ["value", "policy"])},
                        count_steps,
                    )

                    # log stats
                    if update > 0 and update % self.config.LOG_INTERVAL == 0:
                        logger.info("update: {}\tfps: {:.3f}\t".format(
                            update,
                            count_steps /
                            ((time.time() - t_start) + prev_time),
                        ))

                        logger.info(
                            "update: {}\tenv-time: {:.3f}s\tpth-time: {:.3f}s\t"
                            "frames: {}".format(update, env_time, pth_time,
                                                count_steps))
                        logger.info("Average window size: {}  {}".format(
                            len(window_episode_stats["count"]),
                            "  ".join(
                                "{}: {:.3f}".format(k, v / deltas["count"])
                                for k, v in deltas.items() if k != "count"),
                        ))

                    # checkpoint model
                    if update % self.config.CHECKPOINT_INTERVAL == 0:
                        self.save_checkpoint(
                            f"ckpt.{count_checkpoints}.pth",
                            dict(step=count_steps),
                        )
                        count_checkpoints += 1

            self.envs.close()
예제 #2
0
    def train(self) -> None:
        r"""Main method for training DD/PPO.

        Returns:
            None
        """

        self._init_train()

        count_checkpoints = 0
        prev_time = 0

        lr_scheduler = LambdaLR(
            optimizer=self.agent.optimizer,
            lr_lambda=lambda x: 1 - self.percent_done(),
        )

        interrupted_state = load_interrupted_state()
        if interrupted_state is not None:
            self.agent.load_state_dict(interrupted_state["state_dict"])
            self.agent.optimizer.load_state_dict(
                interrupted_state["optim_state"]
            )
            lr_scheduler.load_state_dict(interrupted_state["lr_sched_state"])

            requeue_stats = interrupted_state["requeue_stats"]
            self.env_time = requeue_stats["env_time"]
            self.pth_time = requeue_stats["pth_time"]
            self.num_steps_done = requeue_stats["num_steps_done"]
            self.num_updates_done = requeue_stats["num_updates_done"]
            self._last_checkpoint_percent = requeue_stats[
                "_last_checkpoint_percent"
            ]
            count_checkpoints = requeue_stats["count_checkpoints"]
            prev_time = requeue_stats["prev_time"]

            self._last_checkpoint_percent = requeue_stats[
                "_last_checkpoint_percent"
            ]

        ppo_cfg = self.config.RL.PPO

        with (
            TensorboardWriter(
                self.config.TENSORBOARD_DIR, flush_secs=self.flush_secs
            )
            if rank0_only()
            else contextlib.suppress()
        ) as writer:
            while not self.is_done():
                profiling_wrapper.on_start_step()
                profiling_wrapper.range_push("train update")

                if ppo_cfg.use_linear_clip_decay:
                    self.agent.clip_param = ppo_cfg.clip_param * (
                        1 - self.percent_done()
                    )

                if EXIT.is_set():
                    profiling_wrapper.range_pop()  # train update

                    self.envs.close()

                    if REQUEUE.is_set() and rank0_only():
                        requeue_stats = dict(
                            env_time=self.env_time,
                            pth_time=self.pth_time,
                            count_checkpoints=count_checkpoints,
                            num_steps_done=self.num_steps_done,
                            num_updates_done=self.num_updates_done,
                            _last_checkpoint_percent=self._last_checkpoint_percent,
                            prev_time=(time.time() - self.t_start) + prev_time,
                        )
                        save_interrupted_state(
                            dict(
                                state_dict=self.agent.state_dict(),
                                optim_state=self.agent.optimizer.state_dict(),
                                lr_sched_state=lr_scheduler.state_dict(),
                                config=self.config,
                                requeue_stats=requeue_stats,
                            )
                        )

                    requeue_job()
                    return

                self.agent.eval()
                count_steps_delta = 0
                profiling_wrapper.range_push("rollouts loop")

                profiling_wrapper.range_push("_collect_rollout_step")
                for buffer_index in range(self._nbuffers):
                    self._compute_actions_and_step_envs(buffer_index)

                for step in range(ppo_cfg.num_steps):
                    is_last_step = (
                        self.should_end_early(step + 1)
                        or (step + 1) == ppo_cfg.num_steps
                    )

                    for buffer_index in range(self._nbuffers):
                        count_steps_delta += self._collect_environment_result(
                            buffer_index
                        )

                        if (buffer_index + 1) == self._nbuffers:
                            profiling_wrapper.range_pop()  # _collect_rollout_step

                        if not is_last_step:
                            if (buffer_index + 1) == self._nbuffers:
                                profiling_wrapper.range_push(
                                    "_collect_rollout_step"
                                )

                            self._compute_actions_and_step_envs(buffer_index)

                    if is_last_step:
                        break

                profiling_wrapper.range_pop()  # rollouts loop

                if self._is_distributed:
                    self.num_rollouts_done_store.add("num_done", 1)

                (
                    value_loss,
                    action_loss,
                    dist_entropy,
                ) = self._update_agent()

                if ppo_cfg.use_linear_lr_decay:
                    lr_scheduler.step()  # type: ignore

                self.num_updates_done += 1
                losses = self._coalesce_post_step(
                    dict(value_loss=value_loss, action_loss=action_loss),
                    count_steps_delta,
                )

                self._training_log(writer, losses, prev_time)

                # checkpoint model
                if rank0_only() and self.should_checkpoint():
                    self.save_checkpoint(
                        f"ckpt.{count_checkpoints}.pth",
                        dict(
                            step=self.num_steps_done,
                            wall_time=(time.time() - self.t_start) + prev_time,
                        ),
                    )
                    count_checkpoints += 1

                profiling_wrapper.range_pop()  # train update

            self.envs.close()